胚胎冷冻技术应用于抗菌肽转基因小鼠的保种传代

目的研究胚胎冷冻在抗菌肽转基因FVB小鼠保种传代中的应用。方法对6~8周正常雌性FVB小鼠进行超排分别与雄性杂合子抗菌肽转基因FVB小鼠交配,收集2-cell胚胎,进行胚胎冷冻。1周后进行胚胎复苏移植,通过PCR方法对仔代鉴定。结果冻存胚胎140枚,复苏获得存活胚胎98枚,移植85枚,产仔38只,获得阳性后代12只。结论通过胚胎冷冻技术保种及复苏移植技术可对抗菌肽转基因小鼠进行传代。     

Cryopreservation of seeds and protocorms of rare temperate orchids

The efficiency of cryopreservation of seeds of five rare and endangered species of temperate orchids belonging to Platanthera and Dactylorhiza genera followed by their asymbiotic culture in vitro, as well as of in vitro cultured D. fuchsii protocorms (specific stage of orchid embryo development after release from the seed coat) was investigated. Germination rates of seeds after their exposure to liquid nitrogen were species-depended and could be either higher or lower than in the unfrozen control. There was no significant difference between growth rates of protocorms of the same species obtained from seeds collected in various Russia regions and cultured for 5 months. After vitrification, 9% of D. fuchsii protocorms with a larger diameter of 1200 μm survived cryopreservation; however, their growth was retarded for three months when compared to control protocorms.     

Optimal conditions for cryopreservation of primary chicken embryo kidney cells with dimethyl sulfoxide

Conditions were evaluated for optimum cryopreservation of primary chicken embryo kidney (CEK) cells. The recovery of viable CEK cells was best (50.8% viability) when the concentration of dimethyl sulfoxide (DMSO) in the freezing medium was 20% (v/v). The viability of primary CEK cells was not influenced by the concentration of calf serum in the freezing medium, the duration of storage at −70°C before storage in liquid nitrogen, cell concentration, or the method of addition or dilution of DMSO. Thawed cells recovered and grew in complete growth medium similarly to cells freshly isolated from kidney, and influenza viruses produced plaques in the monolayer. The cryopreservation procedures described here may facilitate maintenance of a standard stock of primary CEK cells for laboratories where preparation of primary CEK cells is not an option.     

Why is intracellular ice lethal? A microscopical study showing evidence of programmed cell death in cryo-exposed embryonic axes of recalcitrant seeds of Acer saccharinum

Background and Aims Conservation of the genetic diversity afforded by recalcitrant seeds is achieved by cryopreservation, in which excised embryonic axes (or, where possible, embryos) are treated and stored at temperatures lower than −180 °C using liquid nitrogen. It has previously been shown that intracellular ice forms in rapidly cooled embryonic axes of Acer saccharinum (silver maple) but this is not necessarily lethal when ice crystals are small. This study seeks to understand the nature and extent of damage from intracellular ice, and the course of recovery and regrowth in surviving tissues.Methods Embryonic axes of A. saccharinum, not subjected to dehydration or cryoprotection treatments (water content was 1·9 g H₂O g⁻¹ dry mass), were cooled to liquid nitrogen temperatures using two methods: plunging into nitrogen slush to achieve a cooling rate of 97 °C s⁻¹ or programmed cooling at 3·3 °C s⁻¹. Samples were thawed rapidly (177 °C s⁻¹) and cell structure was examined microscopically immediately, and at intervals up to 72 h in vitro. Survival was assessed after 4 weeks in vitro. Axes were processed conventionally for optical microscopy and ultrastructural examination.Key Results Immediately following thaw after cryogenic exposure, cells from axes did not show signs of damage at an ultrastructural level. Signs that cells had been damaged were apparent after several hours of in vitro culture and appeared as autophagic decomposition. In surviving tissues, dead cells were sloughed off and pockets of living cells were the origin of regrowth. In roots, regrowth occurred from the ground meristem and procambium, not the distal meristem, which became lethally damaged. Regrowth of shoots occurred from isolated pockets of surviving cells of peripheral and pith meristems. The size of these pockets may determine the possibility for, the extent of and the vigour of regrowth.Conclusions Autophagic degradation and ultimately autolysis of cells following cryo-exposure and formation of small (0·2–0·4 µm) intracellular ice crystals challenges current ideas that ice causes immediate physical damage to cells. Instead, freezing stress may induce a signal for programmed cell death (PCD). Cells that form more ice crystals during cooling have faster PCD responses.     

Alternative procedures for the cryopreservation of brown bear ejaculates depending on the flexibility of the “in cooling” period (5 °C)

The adaptability of cryopreservation protocols for brown bear spermatozoa collected under field conditions and frozen in a nearby laboratory (transported for a few hours) or shipped to a reference laboratory for sex sorting (transported for a few days) was evaluated. Forty-nine electroejaculates from 15 mature brown bears were extended to 100 × 10⁶ sperm/mL in a TES-Tris-Fructose based extender and cryopreserved (−20 °C/min to −100 °C and stored at −196 °C). After thawing, the quality of the seminal samples was assessed for total (TM), progressive (PM) motility and kinetic parameters – by CASA –, and viability (VIAB), viable and non-apoptotic status (YOPRO−), high membrane mitochondrial potential (MIT) and intact acrosomes (iACR) – by flow cytometry –. In Experiment 1, we assessed different storage times (0, 0.5, 1 – control –, 4–5, 7–8 and 11–12 h) at 5 °C from final dilution to freezing. After thawing, non-equilibrated samples (0 h) showed lower values of iACR, TM and PM. No significant differences were found for the different periods of equilibration tested. In Experiment 2, we evaluated three long-term storage times (24, 48 and 72 h) at 5 °C before freezing using storage for 1 h as control. The post-thawing quality of brown bear spermatozoa declined markedly after 48–72 h of pre-freezing. In conclusion, our findings suggest the possibility of extending the pre-freezing cooling period up to 24 h post-collection without freezing. This knowledge should enable the adaptation of the freezing protocols for when a special handling conditions are required such as the shipment of seminal samples to technological centers for the pre-freezing application of enhancer spermatic biotechnologies.     

荒漠甲虫小胸鳖甲抗冻蛋白的酵母表达及应用

昆虫抗冻蛋白(Antifreeze protein,AFP)的抗冻活性很高,可应用于生物组织和细胞的低温保存。为了在酵母中表达荒漠甲虫小胸鳖甲Microdera punctipennis抗冻蛋白Mp AFP698,并确定其在低温下的保护作用,本文通过构建真核表达载体p PIC9K-Mpafp698,转化巴斯德毕赤酵母GS115,诱导表达小胸鳖甲抗冻蛋白Mp AFP698。利用免疫印迹(Western blotting)分析Mp AFP698蛋白的特异性表达,结果显示Mpafp698基因可整合到酵母基因组中并分泌表达,且酵母自身蛋白很少分泌表达。检测抗冻蛋白的低温保护作用,结果发现,小胸鳖甲抗冻蛋白可显著改善冷冻小鼠肝脏等器官的细胞形态,降低血细胞在4℃的溶血率,提高SF9细胞冻融后的存活率。本研究表明,小胸鳖甲AFP可以在毕赤酵母中分泌表达,便于纯化,有良好的低温保护效果。     

Cryopreserved Morulae can be used to Efficiently Generate Germline-transmitting Chimeras by Blastocyst Injection

The production of chimeric mice is a complex process, requiring the careful coordination of tissue culture cell growth, production of a large number (30–75) of competent blastocysts and the availability of appropriately timed pseudo pregnant female mice. Failure at any of these steps can impinge upon the rapid production of chimeras. One potential improvement for the efficient generation of chimeric mice would be the utilization of cryopreserved embryos suitable for injection. C57Bl/6 morulae were frozen using a standard 2-step protocol with ethylene glycol as the cryopreservation agent. We determined that cryopreserved morulae could thaw, culture to blastocyst stage in KSOM media and survive injection at rates equivalent to control embryos. Cryopreserved morulae were also equivalent to controls at all later stages in the process of production of chimeric mice, including birth rate, percentage chimerism of resulting animals and ability to produce germline progeny. Hence, cryopreservation of morulae for blastocyst injection is a suitable option to enhance the efficiency of chimeric mouse generation.     

Intracytoplasmic Sperm Injection Using Cryopreserved, Fixed, and Freeze-dried Sperm in Eggs of Nile Tilapia

Gamete preservation techniques are essential in animal husbandry as well as in assisted reproduction for humans. In this research we attempted to use 3 different sperm preservation techniques in combination with newly developed techniques for intracytoplasmic sperm injection (ICSI) to fertilize eggs of a teleost fish, the Nile tilapia (Oreochromis niloticus). Of 47 eggs injected with fresh sperm, 11 (23%) were fertilized, 5 developed abnormally, and 4 developed normally and hatched; from these, one grew to adulthood. Nuclear DNA content of 4 of the abnormal embryos indicated that they were diploid. Flow cytometric analysis of a blood sample from the surviving ICSI fish collected 2 months after fertilization indicated that the fish was diploid. Of 45 eggs injected with cryopreserved sperm, 9 (20%) developed to the blastula stage. Of 40 eggs injected with sperm preserved in 70% methanol, none were fertilized. No injections were possible with freeze-dried Nile tilapia sperm owing to technical difficulties during manipulation. Although the findings described here are limited, they provide the first steps toward using sperm preservation methods in addition to cryopreservation for fertilization in fishes.     

Polymer-based Preparation of Soil Inoculants: Applications to Arbuscular Mycorrhizal Fungi

Arbuscular mycorrhizal fungi is an important group of soil microorganisms which form beneficial symbiotic associations with roots with a wide range of plants thus improving plant growth, nutrition and health. This paper reviews the current status of preparation and formulation of mycorrhizal inoculum applying polymer materials with determined characteristics. The most widely used methods are based on the entrapment of fungal materials in natural polysaccharide gels. The potential of such inoculant preparations is illustrated by various studies which include immobilization of mycorrhized root pieces, vesicles and spores, in some cases co-entrapped with other plant beneficial microorganisms. Suggestions for further research in this field are also discussed.     

Loss of viability during freeze–thaw of intact and adherent human embryonic stem cells with conventional slow-cooling protocols is predominantly due to␣apoptosis rather than cellular necrosis

Summary A major challenge in the widespread application of human embryonic stem (hES) cells in clinical therapy and basic scientific research is the development of efficient cryopreservation protocols. Conventional slow-cooling protocols utilizing standard cryoprotectant concentrations i.e. 10% (v/v) DMSO, yield extremely low survival rates of <5% as reported by previous studies. This study characterized cell death within frozen–thawed hES colonies that were cryopreserved under standard conditions. Surprisingly, our results showed that immediately after post-thaw washing, the overwhelming majority of hES cells were viable (≈98%), as assessed by the trypan blue exclusion test. However, when the freshly-thawed hES colonies were incubated within a 37 °C incubator, there was observed to be a gradual reduction in cell viability over time. The kinetics of cell death was drastically slowed-down by keeping the freshly-thawed hES colonies at 4 °C, with >90% of cells remaining viable after 90 min of incubation at 4 °C. This effect was reversible upon re-exposing the cells to physiological temperature. The vast majority of low temperature-exposed hES colonies gradually underwent cell death upon incubation for a further 90 min at 37 °C. Terminal deoxynucleotidyl transferase (TdT)-mediated dUTP nick-end-labeling (TUNEL) assay confirmed apoptosis-induced nuclear DNA fragmentation in frozen–thawed hES cells after incubation at 37 °C for 90 min. Expression of active caspase-3 enzyme, which is another prominent marker of apoptosis, was confirmed by immunocytochemical staining, while transmission electron microscopy showed typical ultrastructural features of apoptosis such as chromatin condensation and margination to the nuclear membrane. Hence, our results demonstrated that apoptosis instead of cellular necrosis, is the major mechanism of the loss of viability of cryopreserved hES cells during freeze–thawing with conventional slow-cooling protocols.